Optoelectronic Control refers to the use of optical signals to manage and regulate the behavior of electronic components within photonic systems, particularly in the manipulation of light in micro-ring resonators. This control mechanism is crucial for maintaining system performance, especially in addressing issues like thermal crosstalk that can affect the integrity of analog photonic information processing. By leveraging optoelectronic control, the systems can effectively utilize light to influence electronic operations, enabling improved responsiveness and accuracy in applications such as signal processing and neural network inference.

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Low-Latency Passive Thermal Stabilization of a Silicon Micro-Ring Resonator with Self-Heating

Analog photonic information processing can be implemented with low chip area using wavelength-division multiplexed systems, which typically manipulate light using micro-ring resonators. Micro-rings are uniquely susceptible to thermal crosstalk, with negative system performance consequences if not addressed. Existing thermal sensitivity mitigation methods face drawbacks including high complexity, high latency, high digital and analog hardware requirements, and CMOS incompatibility. Here, we demonstrate a passive thermal desensitization mechanism for silicon micro-ring resonators exploiting self-heating resulting from optical absorption. We achieve a 49% reduction in thermal crosstalk sensitivity and 1 ?s adaptation latency using a system with no specialized micro-ring engineering, no additional control hardware, and no additional calibration. Our theoretical model indicates the potential for significant further desensitization gains with optimized microring designs. Self-heating desensitization can be combined with active thermal stabilization to achieve both responsiveness and accuracy or applied independently to thermally desensitize large photonic systems for signal processing or neural network inference.